#pragma once
#include "gp_Ax3.h"
#include "gp_Pnt.h"
#include "gp_Ax1.h"

class gp_Ax3;
class gp_Ax1;
class gp_Pnt;
class gp_Ax2;
class gp_Trsf;
class gp_Vec;


 


//!  Defines an infinite conical surface. <br>
//! A cone is defined by its half-angle at the apex and <br>
//! positioned in space with a coordinate system (a gp_Ax3 <br>
//! object) and a "reference radius" where: <br>
//! -   the "main Axis" of the coordinate system is the axis of   revolution of the cone, <br>
//! -   the plane defined by the origin, the "X Direction" and <br>
//!   the "Y Direction" of the coordinate system is the <br>
//!   reference plane of the cone; the intersection of the <br>
//!   cone with this reference plane is a circle of radius <br>
//!   equal to the reference radius, <br>
//!   if the half-angle is positive, the apex of the cone is on <br>
//!   the negative side of the "main Axis" of the coordinate <br>
//!   system. If the half-angle is negative, the apex is on the   positive side. <br>
//!   This coordinate system is the "local coordinate system" of the cone. <br>
//! Note: when a gp_Cone cone is converted into a <br>
//! Geom_ConicalSurface cone, some implicit properties of <br>
//! its local coordinate system are used explicitly: <br>
//! -   its origin, "X Direction", "Y Direction" and "main <br>
//!   Direction" are used directly to define the parametric <br>
//! directions on the cone and the origin of the parameters, <br>
//! -   its implicit orientation (right-handed or left-handed) <br>
//!   gives the orientation (direct or indirect) of the <br>
//!   Geom_ConicalSurface cone. <br>
//! See Also <br>
//! gce_MakeCone which provides functions for more <br>
//! complex cone constructions <br>
//! Geom_ConicalSurface which provides additional <br>
//! functions for constructing cones and works, in particular, <br>
//! with the parametric equations of cones gp_Ax3 <br>
class gp_Cone  {

public:

  

  //! Creates an indefinite Cone. <br>
      gp_Cone();
  
//!  Creates an infinite conical surface. A3 locates the cone <br>
//!  in the space and defines the reference plane of the surface. <br>
//!  Ang is the conical surface semi-angle between 0 and PI/2 radians. <br>
//!  Radius is the radius of the circle in the reference plane of <br>
//!  the cone. <br>
//! Raises ConstructionError <br>
//!  . if Radius is lower than 0.0 <br>
//!  . Ang < Resolution from gp  or Ang >= (PI/2) - Resolution. <br>
      gp_Cone(const gp_Ax3& A3,const double Ang,const double Radius);
  //!  Changes the symmetry axis of the cone.  Raises ConstructionError <br>
//!  the direction of A1 is parallel to the "XDirection" <br>
//!  of the coordinate system of the cone. <br>
        void SetAxis(const gp_Ax1& A1) ;
  //! Changes the location of the cone. <br>
        void SetLocation(const gp_Pnt& Loc) ;
  
//!  Changes the local coordinate system of the cone. <br>
//!  This coordinate system defines the reference plane of the cone. <br>
        void SetPosition(const gp_Ax3& A3) ;
  
//!  Changes the radius of the cone in the reference plane of <br>
//!  the cone. <br>//! Raised if R < 0.0 <br>
        void SetRadius(const double R) ;
  
//!  Changes the semi-angle of the cone. <br>
//!  Ang is the conical surface semi-angle  ]0,PI/2[. <br>
//!    Raises ConstructionError if Ang < Resolution from gp or Ang >= PI/2 - Resolution <br>
        void SetSemiAngle(const double Ang) ;
  
//!  Computes the cone's top. The Apex of the cone is on the <br>
//!  negative side of the symmetry axis of the cone. <br>
        gp_Pnt Apex() const;
  //! Reverses the   U   parametrization of   the  cone <br>
//!          reversing the YAxis. <br>
        void UReverse() ;
  //! Reverses the   V   parametrization of   the  cone  reversing the ZAxis. <br>
        void VReverse() ;
  //! Returns true if the local coordinate system of this cone is right-handed. <br>
        bool Direct() const;
  //! returns the symmetry axis of the cone. <br>
       const gp_Ax1& Axis() const;
  
//!  Computes the coefficients of the implicit equation of the quadric <br>
//!  in the absolute cartesian coordinates system : <br>
//! A1.X**2 + A2.Y**2 + A3.Z**2 + 2.(B1.X.Y + B2.X.Z + B3.Y.Z) + <br>
//! 2.(C1.X + C2.Y + C3.Z) + D = 0.0 <br>
       void Coefficients(double& A1,double& A2,double& A3,double& B1,double& B2,double& B3,double& C1,double& C2,double& C3,double& D) const;
  //! returns the "Location" point of the cone. <br>
       const gp_Pnt& Location() const;
  
//!  Returns the local coordinates system of the cone. <br>
       const gp_Ax3& Position() const;
  
//!  Returns the radius of the cone in the reference plane. <br>
        double RefRadius() const;
  //! Returns the half-angle at the apex of this cone. <br>
        double SemiAngle() const;
  //! Returns the XAxis of the reference plane. <br>
        gp_Ax1 XAxis() const;
  //! Returns the YAxis of the reference plane. <br>
        gp_Ax1 YAxis() const;
  
       void Mirror(const gp_Pnt& P) ;
  
//!  Performs the symmetrical transformation of a cone <br>
//!  with respect to the point P which is the center of the <br>
//!  symmetry. <br>
       gp_Cone Mirrored(const gp_Pnt& P) const;
  
       void Mirror(const gp_Ax1& A1) ;
  
//!  Performs the symmetrical transformation of a cone with <br>
//!  respect to an axis placement which is the axis of the <br>
//!  symmetry. <br>
       gp_Cone Mirrored(const gp_Ax1& A1) const;
  
       void Mirror(const gp_Ax2& A2) ;
  
//!  Performs the symmetrical transformation of a cone with respect <br>
//!  to a plane. The axis placement A2 locates the plane of the <br>
//!  of the symmetry : (Location, XDirection, YDirection). <br>
       gp_Cone Mirrored(const gp_Ax2& A2) const;
  
        void Rotate(const gp_Ax1& A1,const double Ang) ;
  
//!  Rotates a cone. A1 is the axis of the rotation. <br>
//!  Ang is the angular value of the rotation in radians. <br>
        gp_Cone Rotated(const gp_Ax1& A1,const double Ang) const;
  
        void Scale(const gp_Pnt& P,const double S) ;
  
//!  Scales a cone. S is the scaling value. <br>
//!  The absolute value of S is used to scale the cone <br>
        gp_Cone Scaled(const gp_Pnt& P,const double S) const;
  
        void Transform(const gp_Trsf& T) ;
  
//!  Transforms a cone with the transformation T from class Trsf. <br>
        gp_Cone Transformed(const gp_Trsf& T) const;
  
        void Translate(const gp_Vec& V) ;
  
//!  Translates a cone in the direction of the vector V. <br>
//!  The magnitude of the translation is the vector's magnitude. <br>
        gp_Cone Translated(const gp_Vec& V) const;
  
        void Translate(const gp_Pnt& P1,const gp_Pnt& P2) ;
  
//!  Translates a cone from the point P1 to the point P2. <br>
        gp_Cone Translated(const gp_Pnt& P1,const gp_Pnt& P2) const;
    const gp_Ax3& _CSFDB_Getgp_Conepos() const { return pos; }
    double _CSFDB_Getgp_Coneradius() const { return radius; }
    void _CSFDB_Setgp_Coneradius(const double p) { radius = p; }
    double _CSFDB_Getgp_ConesemiAngle() const { return semiAngle; }
    void _CSFDB_Setgp_ConesemiAngle(const double p) { semiAngle = p; }



protected:




private: 


gp_Ax3 pos;
double radius;
double semiAngle;


};






// other  functions and methods (like "C++: function call" methods)



